Essential element management

ABSTRACT

The invention extends the utility of apparatus used to extract medicinal  cannabis  compounds into an eluate by separating a portion of medicinal  cannabis  compounds contained within a portion of eluate at a first extraction target level providing enough clean solvent to continue extraction operations. A high efficiency concentrator such as a rotary evaporator or a wiped film evaporator processes eluate from one or more tanks or extraction vessels creating clean solvent when extraction targets are met or when clean solvent is exhausted. This manages eluate concentration levels and limits the quantity of concentrated medicinal  cannabis  compounds on site at any moment in time. The invention enables a business model for keeping medicinal  cannabis  compounds within a legal system, and reduces pollution because law enforcement would no longer have to burn large quantities of  cannabis  plant matter.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of and claims priority benefit of U.S. patent application Ser. No. 15/997,633, filed Jun. 4, 2018, now U.S. Pat. No. 10,849,949, which is a continuation and claims priority benefits of U.S. patent application Ser. No. 14/880,260, filed Oct. 11, 2015 now U.S. Pat. No. 9,987,319, which is a continuation and claims priority benefit of U.S. patent application Ser. No. 13/655,410, filed Oct. 18, 2012, now U.S. Pat. No. 9,155,767, the disclosures which are incorporated herein by reference.

JOINT RESEARCH AGREEMENT

At the time of the presently disclosed invention inventors Andrew D. Hospodor and Robert J. Rapp were parties to a joint research agreement.

BACKGROUND OF THE INVENTION

The federal government of the United States as typified by the Drug Enforcement Agency (DEA), Federal Bureau of Investigation (FBI), and Federal Drug Administration (FDA) consider cannabis an illegal substance with no medicinal value. In 2009 the DEA confiscated and burned 2980 metric tons (nearly 6.6 million pounds, or 7,000,000 cannabis plants) of cannabis plants nearly doubling the 1539 metric tons confiscated and burned in 2008. The FY 2012 DEA Performance Budget Congressional Submission indicates that the DEA eradicated 9,000,000 cannabis plants in FY 2010 and 2011, and projects 9,500,000 plants (over 4000 metric tons, or 8.8 million pounds) to be eradicated in FY 2013. The burning of millions of cannabis plants emits large amounts carbon, dioxin, gasoline vapors, and other pollutants into the environment.

In contrast, the medicinal use of cannabis has been legalized and regulated in the District of Columbia, and in 17 states. The legalization of medicinal cannabis in these municipalities has led to an expansion of a state regulated distribution of cannabis flowers, edible medications, and topical medications available to individuals with proper credentials or recommendations. In an effort to lead the way in providing controlled dosage medications certain technologies have been developed that include the extraction of medicinal cannabis compounds from raw cannabis in large volumes followed by incorporation of controlled dosages of medicinal cannabis compounds into edible or topical medications. For example, it is now possible to manufacture predominantly non-psychoactive medications derived from cannabis. Characteristically different forms of medical cannabis compounds can now be studied in ways not possible before.

The most significant driver for growing demand for legalized medicinal cannabis are the increasing bodies of research showing tangible benefits to individuals suffering from a plurality of ailments when using medicinal cannabis. Furthermore, no toxic or overdose effects from the use of cannabis have been medically documented.

In past years various mechanisms for extracting essential elements from raw cannabis plant material have been researched by professional scientists, until recently the extraction of medicinal compounds from cannabis has been limited to small scale extractions by authorized scientists in the academic realm or has been performed clandestinely by individuals operating outside the law. The Applicant's related patent application Ser. No. 13/066,585, now U.S. Pat. No. 8,343,553, and Ser. No. 13/506,010 relate to extracting medicinal cannabis compounds in large volumes from cannabis plant material. The invention described in this patent application extends the utility of apparatus built consistent with the Applicant's previous extraction apparatuses.

As of 2012 states with laws regulating the medicinal use of cannabis have not implemented or officially sanctioned any strategy designed to manage cannabis waste materials (cannabis leaves, trim, imperfect bud material, insect infested, or moldy plants). Cannabis plants grown by authorized medical marijuana growers produce materials have been dispensed to patients through dispensaries, yet many patients and dispensaries are not interested is cannabis leaves, cannabis trimmings, or imperfect bud material. Furthermore, moldy cannabis plant material or insect infested plant material can cause allergic reactions, fungal infections, or have other negative side effects if consumed by people with compromised immune systems. Without effective strategies for capturing medicinal cannabis compounds contained within such “waste” cannabis plant material poses a risk that these materials may be diverted into gray or black markets or end up in rivers, streams, or in landfills.

The focus of the present invention relates to an improved apparatus, process, and business methods for extracting medicinal elements from cannabis plant material and then keeping cannabinoids within a legal system without emitting vast amounts of pollution into the environment.

SUMMARY OF THE PRESENTLY CLAIMED INVENTION

The Applicant hereby incorporates by reference his earlier patent application Ser. No. 13/066,585 entitled Essential Element Extractor and Ser. No. 13/506,010 Recycling Cannabinoid Extractor into this patent application.

The Applicant's earlier inventions described in patent application Ser. No. 13/066,585 (Essential Element Extractor) and Ser. No. 13/506,010 (Recycling cannabinoid extractor) describe processes and apparatus used to extract medicinal cannabis compounds from cannabis plant material and store them in an eluate. Such an eluate contains low concentrations of medicinal cannabis compounds per unit volume of solvent is stored in a storage tank or a “dirty tank”; the Applicant's tank or entire extraction apparatus is also typically configured to be transported on or by a vehicle. After a plurality of extractions the Applicant's eluate accumulates medicinal cannabis compounds creating “dirty” solvent. Eventually clean solvent transported into the field thus becomes dirty. Sufficiently dirty solvent reduces the efficiency of the apparatus because without clean solvent to rinse the cannabis plant material after extraction a low density residue of medicinal cannabis compounds may be left on the cannabis plant matter after extraction. Furthermore, repeated extractions using dirty solvent may cause the Applicant's eluate to exceed targeted concentrations of medicinal cannabis compounds per unit volume of solvent.

The Applicant's improved invention separates a portion of medical cannabis compounds contained in a portion of an eluate creating a more concentrated portion of dirty eluate or a concentrate of medicinal cannabis compounds and a portion of clean solvent. To accomplish this, a high efficiency concentrator such as a rotary evaporator (roto-vap) or a wiped film evaporator processes eluate from the Applicant's dirty tank or eluate output from his extraction vessel or “hopper” as referred to in the Applicant's earlier patent applications referenced above and incorporated within this disclosure. The invention also includes a business model for managing essential elements contained within cannabis by keeping them within a legal system until they are consumed or destroyed. The invention is, thus, an improved apparatus, process, and a business method.

The Applicant's invention enables law enforcement to stop burning cannabis plants in the field while allowing operations in the field to continue virtually indefinitely. This eliminates the need for law enforcement to pollute the atmosphere by burning millions of pounds of cannabis they confiscate each year.

The invention also allows municipalities with medicinal marijuana laws to enact strategies for recovering medicinal cannabis compounds from waste cannabis materials and keep them within that states legal system.

The Applicant's invention thus eliminates dis-advantages inherent in diametrically opposed theaters of the debate about how cannabis should be treated in our society. It provides benefits to those who wish to regulate cannabis as a medication and to those who wish to eradicate cannabis because it is an illegal substance under Federal law.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary “Mobile Extractor in Semi Cross Section.”

FIG. 2: illustrates an exemplary “Mobile Extractor Mounted on a Truck.”

FIG. 3: illustrates an exemplary “Hopper Configured for Dumping”.

FIG. 4: illustrates an exemplary truck containing a clean tank, a first dirty tank, a hopper, pumps, valves, and a high efficiency concentrator.

DETAILED DESCRIPTION OF THE INVENTION

The Applicant hereby incorporates by reference his earlier patent application Ser. No. 13/066,585 entitled Essential Element Extractor and Ser. No. 13/506,010 Recycling Cannabinoid Extractor into this patent application.

The Applicant's earlier inventions described in patent application Ser. No. 13/066,585 (Essential Element Extractor) and Ser. No. 13/506,010 (Recycling cannabinoid extractor) describe processes and apparatus used to extract medicinal cannabis compounds from cannabis plant material and store them in an eluate. Such an eluate contains low concentrations of medicinal cannabis compounds per unit volume of solvent is stored in a storage tank or a “dirty tank”; the Applicant's “dirty” tank or entire extraction apparatus is also typically configured to be transported on or by a vehicle. After a plurality of extractions the Applicant's eluate accumulates medicinal cannabis compounds creating “dirty” solvent. Eventually all clean solvent transported into the field thus becomes dirty. Sufficiently dirty solvent reduces the efficiency of the apparatus because without clean solvent to rinse the cannabis plant material after extraction a low density residue of medicinal cannabis compounds may be left on the cannabis plant matter after extraction. Furthermore, repeated extractions using dirty solvent may cause the Applicant's eluate to exceed targeted concentrations of medicinal cannabis compounds per unit volume of solvent.

The Applicant's earlier inventions include an extraction vessel (a “hopper”) in controlled fluid communication with one or more solvent tanks; some embodiments include a clean configured to contain clean solvent and a dirty tank configured to contain an eluate of medicinal cannabis compounds and solvent.

The Applicant's improved invention separates a portion of medical cannabis compounds contained in a portion of an eluate creating a more concentrated portion of dirty eluate or a concentrate of medicinal cannabis compounds and a portion of clean solvent. To accomplish this, a high efficiency concentrator such as a rotary evaporator (roto-vap) or a wiped film evaporator processes eluate from the Applicant's dirty tank or eluate output from his extraction vessel or “hopper” as referred to in the Applicant's earlier patent applications referenced above and incorporated within this disclosure. The invention also includes a business model for managing essential elements contained within cannabis by keeping them within a legal system until they are consumed or destroyed. The invention is thus an improved apparatus, process, and a business method.

The Applicant's current invention extends the utility and efficiency of the Applicant's earlier inventions because clean solvent may be produced to continue field operations. Without the ability to create at least a small amount of clean solvent, field operation would have to be paused until additional clean solvent were transported on site.

-   -   A high efficiency concentration apparatus is an apparatus         capable of quickly concentrating at least a portion of medicinal         cannabis compounds by separating them from solvent used in         previous extractions. Examples of a high efficiency         concentration apparatus include a wiped film evaporator or a         rotary evaporator (roto-vap), each are evaporative separators.         Here again the Applicant's apparatus or portion of the         Applicant's apparatus are typically configured for transport one         or by a vehicle.         -   After the Applicant's extraction apparatus completes a             plurality of extractions, the Applicant's dirty tank will             contain a “targeted volume of eluate” or an eluate that             contains a “targeted concentration level of medicinal             cannabis compounds per unit volume of solvent”.         -   The Applicant hereby defines the term “extraction targets”             to mean either a “targeted volume of eluate” or a “targeted             concentration level of medicinal cannabinoids per unit             volume of solvent”.         -   The Applicant also hereby defines “extraction target tiers”             as meaning either a set of increasing “targeted volumes of             solvent” or a set of increasing “targeted concentration             levels of medicinal cannabis compounds per unit volume of             solvent”.         -   In some embodiments of the Applicant's invention, the total             amount of medicinal cannabis compounds or the density of             medicinal cannabis compounds contained in one eluate or in a             plurality of eluates can be controlled by using             pre-determined regimens.         -   The Applicant's improved invention couples a high efficiency             concentration apparatus to his dirty tank and/or to his             hopper for use when required or desired. For example, the             high efficiency concentration apparatus may be used to             separate a portion of the medicinal cannabis compounds from             a portion of dirty solvent. The high efficiency             concentration apparatus would have two outputs: 1. a more             concentrated eluate or a concentrate of medicinal cannabis             compounds; 2. clean solvent.

Extraction targets may be set based on various parameters that include yet are not limited to: volumes of eluate, measurements of eluate concentration, or combination thereof. Extraction targets include yet are not limited to: the weight of cannabis plant matter extracted within a volume of solvent, the number of plants or portion of plants extracted within a volume of solvent, a measurement of the volumetric density of medicinal cannabis compounds contained within the Applicant's eluate, a visual indication such as the opaqueness of the Applicant's eluate, and/or measurement of residual medicinal cannabis compounds contained within cannabis plant matter after extraction.

The Applicant's invention also controls eluate concentration density in various ways and may be configured to concentrate desired amounts of eluate to produce a desired amount of clean solvent. The Applicant's improved invention allows more raw cannabis to be extracted into eluate on an as needed basis. When certain extraction targets are met and more cannabis becomes available, controlled amounts of clean solvent may be produced allowing field operations to continue.

-   -   For example, if a first target concentration density of         medicinal cannabis compounds is 0.5 milligrams per milliliter of         solvent was attained, a concentration protocol could be         initiated wherein 25 liters of eluate were separated into 20         liters of clean solvent and 5 liters of more concentrated         eluate. The concentration density of medicinal cannabis         compounds in the more concentrated second eluate would be 2.5         milligrams per milliliter (12.5 milligrams in 5 liters).     -   The more concentrated eluate then could be a. Mixed back into         the dirty tank slightly increasing the concentration density in         the dirty tank, b. Stored in a second dirty tank, or c.         Concentrated further and cared for under a security protocol.     -   This process could be repeated until a. A second target         concentration density of medicinal cannabis compounds is reached         in the dirty tank, b. The second dirty tank is full, or c. The         concentrate is moved offsite or destroyed as required by a         desired security protocol.

The Applicant's invention is not limited any specific targeted concentration of eluate as virtually any target concentration of medicinal cannabis compounds per unit volume of solvent may be set.

The Applicant's process and apparatus scales from smaller (pickup/flatbed truck sized), to medium (semi-truck sized), and to fixed placed stationary factory embodiments

-   -   Another example of the Applicant's invention includes a wiped         film evaporator connected to a dirty tank or to an extraction         vessel such as the Applicant's “hopper”. When an extraction         target is met or exceeded a certain amount of eluate can be         transferred from the Applicant's dirty tank and/or the         Applicant's hopper to the wiped film evaporator.

Such a wiped film evaporator configured to separate 75% of solvent from 100 liters of eluate in a single pass would provide 75 liters of clean solvent and 25 liters of a more concentrated eluate. If the initial eluate contained 10 milligrams of medicinal cannabis compounds per milliliter of eluate, 100 liters of such an eluate would contain 100 grams of medicinal cannabis compounds. The more concentrated eluate would contain 100 grams of medicinal cannabis compounds in 25 liters of eluate or 40 milligrams of medicinal cannabis compounds per milliliter of eluate after one pass through the wiped film evaporator. If the eluate were cycled through the wiped film evaporator many times additional clean solvent and a concentrate of medicinal cannabis compounds would be created.

-   -   The Applicant's notes that his improved invention also prevents         the accumulation of a residue of medicinal cannabis compounds on         extracted plant matter, because clean solvent would always be         available to rinse the cannabis plant matter after an         extraction.     -   In certain embodiments the Applicant's improved invention         creates a concentrate of medicinal cannabis compounds; the         presence of such a concentrate is at higher risk of being stolen         than the Applicant's eluate because it is a highly valued drug         substance in a concentrated form. In order to mitigate the         possibility of theft security protocols or conventions may be         incorporated into the operation of the Applicant's improved         invention.         -   Security conventions include yet are not limited to a plan,             a set of rules, or an apparatus used to protect or destroy             the concentrated medicinal cannabis compounds.         -   Examples of security protocols/conventions:             -   On site law enforcement or authorized personnel that                 take possession of concentrated medicinal cannabis                 compounds as they are produced.             -   The destruction of concentrated medicinal cannabis                 compounds on site by authorized personnel, or by law                 enforcement.             -   Supervision of all extraction/concentration activities                 by authorized personnel, or law enforcement.             -   The immediate incorporation of the concentrated cannabis                 compounds into medicinal products on site.             -   The secure isolation and transport of concentrated                 medicinal cannabis compounds to a facility where they                 may be incorporated into medicinal products or                 destroyed.             -   Transportation of extractors on separate vehicles from                 high efficiency concentration apparatuses.             -   The sequestering of medicinal cannabis compounds into                 elements that cannot be consumed, eaten, or smoked.             -   The vaporization of medicinal cannabis compounds from a                 concentrate of medicinal cannabis compounds.             -   Obfuscation of the presence of high efficiency                 concentration apparatuses on a vehicle transporting                 extraction apparatuses.

Preferred embodiments of the invention are configured to transport the Applicant's eluate containing a low concentration of medicinal cannabis compounds per unit volume of solvent without transporting a concentrate of medicinal cannabis compounds on or by the same vehicle as the Applicant's eluate, extraction apparatus, or highly efficient concentration apparatus. In these embodiments a thief would not have easy access to concentrated medicinal cannabis compounds.

Embodiments of the invention where an extraction apparatus is transported on or by a vehicle and a highly efficient concentration apparatus are transported on or by a different vehicle; thieves who stole one apparatus and not the other would not be enabled to perform both extractions and concentrations because they would only have one apparatus and not the other.

The Applicant's invention enables law enforcement to stop burning cannabis plants in the field while allowing operations in the field to continue virtually indefinitely. This eliminates the need for law enforcement to pollute the atmosphere by burning millions of pounds of cannabis they confiscate each year.

The invention also allows municipalities with medicinal marijuana laws to enact strategies for recovering medicinal cannabis compounds from waste materials and keep them within that states legal system.

The Applicant's invention thus eliminates dis-advantages inherent in diametrically opposed theaters of the debate about how cannabis should be treated in our society. It provides benefits to those who wish to regulate cannabis as a medication and also to those who wish to eradicate cannabis because it is an illegal substance under Federal law.

The invention also enables a new business model that may be operated under the supervision of law enforcement eradicating cannabis while minimizing pollution, or under the authorization of state medical marijuana laws.

The business method includes:

-   -   The authorized extraction of medicinal cannabis compounds from         cannabis plant matter in the field.     -   Security by containing low concentrations of medicinal cannabis         compounds into a volume of solvent.     -   Secondary security measures that regulate how concentrates are         to be handled in the field and/or in a secure processing         facility.

Apparatus in such a business model may be operated by the principal who developed the technology on a contractual basis, may be operated by authorized leases, or by licensing the technology to entities regionally.

The apparatus of the invention is not limited to a single extraction system, hopper (extraction vessel), solvent tank, or high efficiency concentrator. The invention may contain a plurality of hoppers, extraction systems, solvent tanks, or high efficiency concentrators. Check valves may also be incorporated into the invention to prevent back flow from one vessel or portion of the apparatus and another. Nonflammable gas may also be introduced into one or more of the vessels in the apparatus and may be used to displace oxygen or be applied under pressure to facilitate fluid flow from one vessel to another. Pressure relief valves may also be used to prevent over pressurization of a tank and be used to vent excess nonflammable gas to the environment or to a solvent vapor trap. A solvent vapor trap may contain a filter such as an activated carbon filter or include a cooled tank or compensator. A preferred nonflammable gas is nitrogen.

DETAILED DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary “Mobile Extractor in Semi Cross Section.” FIG. 1 entitled “Mobile Extractor in Semi Cross Section” shows:

-   -   A clean tank CT filled with a clean solvent CS; a hopper H with         hopper cover HC is connected to the clean tank CT by a hose HS,         portions of the hose HS within the clean tank CT and within the         hopper H are shown with dashed lines indicating that a portion         of the hose H is inside the hopper H and inside the clean tank         CT.     -   Inside of the hopper H is a nozzle N (shown with dashed lines)         and plant material PM is shown in gray. The hopper is connected         to a hopper valve HV to the dirty tank DT by a pipe P. When the         hopper valve is closed solvent will not flow from the hopper H         to the dirty tank DT. The dirty tank is shown containing a         portion of dirty solvent DS. The hopper also is depicted as         having a vent, item VN.     -   A solvent valve (fuel or solvent pump) item SV is located on the         clean tank and is attached to hose HS, the solvent valve when         open will allow clean solvent CS to be sucked into the hopper by         the vacuum pump VP. When closed solvent valve SV will block the         flow of clean solvent CS from the clean tank to the hopper. Item         SV alternatively may be a conventional fuel pump used to pump         solvent from the clean tank to the hopper. The solvent valve         item SV may alternatively be a pump configured to pump solvent         (i.e.: a fuel or solvent pump) that actively pumps solvent from         the clean tank to the hopper.     -   Vacuum hoses connect the vacuum pump VP to the hopper H and to         the dirty tank DT. Two separate vacuum valves VV1 and VV2         connect two separate vacuum hoses VVH to the hopper H and to the         dirty tank DT respectively. Each valve VV1 and VV2 may be         operated independently; they provide vacuum pressure to the         mobile extractor as desired. When VV1 is open, the hopper H has         a vacuum applied to it, when VV2 is open the dirty tank DT has a         vacuum pressure applied to it.

By opening vacuum valve 1 VV1, when vacuum valve 2 VV2 is closed, a vacuum pressure is applied to the hopper H, this causes solvent to be sucked into the hopper from the clean tank CT when the solvent valve SV is open. At this point in time hopper valve HV is typically closed. The vacuum will cause the hopper H to fill with clean solvent CS. This is when the plant material is soaked or washed with clean solvent CS.

Evacuating the hopper: When vacuum valve 1 VV1 is open, when vacuum valve 2 VV2 is closed, when the hopper valve HV is open, and when the solvent valve SV is closed solvent will be sucked and forced by gravity into the dirty tank DT through pipe P; In this state vacuum pressure is applied to the hopper H and the dirty tank DT causing the hopper H to be sucked dry, vent, item VN if opened slightly will allow air to enter the hopper increasing the efficiency of this process. Typically a screen or filter (not depicted) located between the hopper H and the hopper valve HV will prevent plant material PM from falling into the dirty tank DT. A portion of pipe P extending into the dirty tank DT is shown with dashed lines. The Applicant's hopper valve HV may be a pump configured to pump solvent (such as a fuel or solvent pump).

Rinsing the plant material: When vacuum valve 1 VV1 is open, when solvent valve SV is open, when hopper valve HV is open clean solvent CS will be sucked from the clean tank CT into the hopper H, through the plant material PM, and into the dirty tank DT; at this point in time vacuum valve 2 will typically be closed, yet if vacuum valve 2 VV2 were open the plant material PM would still be rinsed by the solvent and the solvent would still flow into the dirty tank DT becoming dirty solvent DS. In this state vacuum pressure may be applied to the entire system.

Also connected to the clean tank is input valve IV, this valve is typically closed, yet may be opened to add more clean solvent CS into the clean tank CT.

Another valve, the drain valve DV is connected to the bottom of the dirty tank DT, the drain valve DV is typically closed, yet when open will cause the dirty solvent DS to drain out of the dirty tank DT.

FIG. 2: illustrates an exemplary “Mobile Extractor Mounted on a Truck.” FIG. 2: entitled “A Mobile Extractor Mounted on a Truck” shows:

-   -   A truck T on which elements of the mobile extractor are mounted:         the clean tank CT with input valve IV and solvent valve SV are         depicted.     -   The solvent valve SV (or pump) is again connected to the hopper         H by a hose HS; the hopper H is connected to a hopper valve HV         (or pump configured to pump solvent) which in turn is connected         to a pipe P and to the dirty tank DT; a vent VN on the hopper is         also depicted. For sake of clarity the vacuum pump, vacuum         hoses, vacuum valves, and the drain valve that were depicted in         FIG. 1 are not shown in FIG. 2.

FIG. 3: illustrates an exemplary “Hopper Configured for Dumping”. FIG. 3: entitled “Hopper Configured for Dumping” depicts a wheel barrow shaped hopper H on truck T.

-   -   The top figure in FIG. 3 shows the hopper H in its working         position.     -   Also depicted are hopper cover HC with a hinge HN, hose HS,         solvent valve or fuel pump, item SV, the clean tank CT, the         dirty tank DT, a hopper valve (or pump) HV, a pipe P connecting         the hopper valve HV to the dirty tank DT, and input valve IV.         Item R is a rotational member; it is an apparatus that allows         the hopper H to be rotated and dumped. The bottom figure in FIG.         3 shows all of the elements mentioned above (hopper H, hinge HN,         hopper cover HC, hose HS, solvent valve or fuel pump SV, clean         tank CT, dirty tank DT, hopper valve (or pump) HV, pipe P, input         valve IV, and rotational member R) yet shows the hopper H in the         dumping configuration where hopper cover HC opens using hinge         HN; this allows contents of the hopper H to be dumped. Also         depicted is adaptor A, adaptor A allows the hopper to be         connected to hopper valve (or pump) HV in a secure way.     -   Note that hose HS connects to the hopper near the point of         rotation R of the hopper H, this allows the hopper H to be         dumped without stressing or pulling on the hose HS.     -   The Applicant notes that the apparatus depicted in his FIGS. 1-3         depict embodiments of apparatus consistent with his earlier         invention, those inventions are not limited to these         embodiments.

FIG. 4: illustrates an exemplary truck containing a clean tank, a first dirty tank, a hopper, pumps, valves, and a high efficiency concentrator. FIG. 4: The Applicant's FIG. 4 depicts a truck T containing a clean tank CT, a first dirty tank DT1, a hopper H, pumps P1 P2 and P3, valves V1 and V2, a high efficiency concentrator HEC, a second dirty tank DT2, and hoses (or pipes) HS1 through HS7.

-   -   The extraction system includes the clean tank CT, the first         dirty tank DT1, the hopper H, pumps P1 P2 and P3.     -   Valve V1 is configured to switch solvent flow from hose HS1 to         the hopper H through valve V1 and hose HS2, or from hose HS1 to         the high efficiency concentrator HEC through valve V1 and hose         HS5. Valve V1 thus is configured to control whether eluate flows         from the first dirty tank DT1 through pump P2 and into the         hopper H or into the high efficiency concentrator when pump P2         pumps eluate.     -   Valve V2 is configured to control solvent flow from the hopper H         through hose HS3, valve V2 and into the first dirty tank through         hose HS4; or to the high efficiency concentrator HEC through         hose HS3, valve V2, and hose HS5.     -   Hose HS6 is configured to transport an eluate from the high         efficiency concentrator to the second dirty tank DT2. Hose HS7         is configured to transport clean solvent output by the high         efficiency concentrator HEC to the clean tank.     -   In this embodiment the high efficiency concentrator HEC can thus         separate clean solvent from an eluate sourced from the first         dirty tank DT1 or from the hopper H and to create a more         concentrated eluate that is stored in the second dirty tank DT2. 

1. A method for processing cannabinoids from cannabis plant matter, the process comprising: controlling the transportation of a first cannabinoid-containing eluate that includes a mixture of solvent and cannabinoids to an input of an evaporator after performing a first extraction at an extraction vessel that contains the cannabis plant matter, the extraction vessel and the evaporator part of a closed-loop extraction-concentration system that includes a first output of the extraction vessel and the input of the evaporator; recovering clean solvent from the first output of the evaporator when performing an evaporation associated with the first cannabinoid-containing eluate, the clean solvent recovered based on the operation of the closed-loop extraction-concentration system and the first extraction being performed; controlling the transportation of at least one of a portion of the clean solvent or additional clean solvent to the extraction vessel, thereby creating a second cannabinoid-containing eluate; and transporting the second cannabinoid-containing eluate to the input of the evaporator.
 2. The method of claim 1, further comprising mitigating solvent from escaping the closed-loop extraction-concentration system by maintaining a sealed opening of the extraction vessel, the opening for receiving the cannabis plant matter, when the first cannabinoid containing eluate is created and when the second cannabinoid containing eluate is created, wherein the first cannabinoid-containing eluate includes a higher concentration of cannabinoids than the second cannabinoid-containing eluate based on the at least portion of the recovered clean solvent rinsing residual cannabinoids from the cannabis plant matter after the first extraction.
 3. The method of claim 1, further comprising establishing a fluid communication between the first output of the extraction vessel and the input of the evaporator to facilitate the transportation of at least one of the first cannabinoid-containing eluate or the second cannabinoid containing eluate.
 4. The method of claim 1, further comprising transporting a third cannabinoid-containing eluate from a second output of the evaporator to an output tank.
 5. The method of claim 2, further comprising transporting at least one of the first cannabinoid-containing eluate or the second cannabinoid-containing eluate to an eluate tank before performing at least one of the evaporation or a second evaporation at the evaporator.
 6. The method of claim 3, wherein the establishing the fluid communication includes opening a valve located between the first output of the extraction vessel and the input of the evaporator.
 7. The method of claim 1, wherein the transporting the first cannabinoid-containing eluate includes pumping of the first cannabinoid-containing eluate with a pump.
 8. The method of claim 1, further comprising establishing a vacuum in the extraction vessel to facilitate the control of the transportation of at least one of a portion of the clean solvent or additional clean solvent to the extraction vessel.
 9. The method of claim 1, further comprising placing the cannabis plant matter in the extraction vessel before moving the solvent into the extraction vessel.
 10. The method of claim 9, further comprising emptying the extraction vessel of the cannabis plant matter and placing a set of second cannabis plant matter into the extraction vessel.
 11. The method of claim 4, further comprising transferring the third cannabinoid-containing eluate from the output tank to the evaporator to produce a fourth cannabinoid-containing eluate.
 12. The method of claim 11, further comprising transporting the fourth cannabinoid-containing eluate from the second output of the evaporator to the output tank.
 13. The method of claim 1, further comprising transporting the recovered clean solvent to a solvent tank.
 14. The method of claim 1, further comprising transporting, by a vehicle, at least one of the evaporator and the extraction vessel to a destination.
 15. The method of claim 1, wherein the evaporator is a wiped-film evaporator.
 16. The method of claim 1, wherein the evaporator is a rotary evaporator.
 17. The method of claim 1, further comprising switching one or more valves by operation of an electronic control system when controlling the first extraction.
 18. The method of claim 17, further comprising controlling one or more pumps by the operation of the electronic control system when controlling the first extraction.
 19. The method of claim 18, with the transporting step comprising transporting, by a truck, at least the evaporator and the extraction vessel.
 20. The method of claim 1, further comprising removing residual solvent from the cannabis plant matter by circulating a gas through the cannabis plant matter and collecting the residual solvent based on the movement of the gas through the cannabis plant matter. 